KR20160120306A - Continuous kneading device - Google Patents

Abstract

The continuous kneading apparatus 1 is provided with a pair of kneading rotors 3 and it is possible to increase the meshing of the kneading rotors 3 while suppressing the kneading load applied to these kneading rotors 3. The continuous kneading apparatus 1 includes a barrel 2 and a pair of kneading rotors 3 accommodated in the barrel 2 and rotating in a state of being engaged with each other in different directions, And a plurality of kneading flights (11, 15) for kneading the material supplied into the barrel (2). The kneading flights 11 and 15 and the portions of the barrel 2 accommodating the kneading flights 11 and 15 constitute a plurality of kneading portions arranged along the axial direction of the kneading rotor 3, respectively. The material is fed in the axial direction from the kneading portion on the upstream side to the kneading portion on the downstream side and kneaded successively. Kneading kneading flight (15) constituting part of the downstream portion of the plurality of kneading has a rotational outer diameter larger than the outer diameter of rotation (D ₁₎ (D ₂₎ of the kneading flight 11 constituting the upstream side of the kneading.

Description

Technical Field [0001] The present invention relates to a continuous kneading apparatus,

The present invention relates to a continuous kneading apparatus for continuously kneading a material such as a resin.

Conventionally, as a continuous kneading apparatus for continuously kneading a material such as a resin, there is one disclosed in Patent Document 1, and the like. The continuous kneading apparatus disclosed in Patent Document 1 includes a barrel having an inner cavity and a pair of kneading rotors accommodated in the barrel. The pair of kneading rotors are arranged such that their axial centers are substantially parallel, and they are rotatable in different directions. In such a continuous kneading apparatus, a material supplied in a barrel is guided between kneading rotors rotating in different directions, and a kneading screw provided on the kneading rotor applies a shearing force to the material, whereby the material is kneaded.

However, in recent years, it has been required to knead kneading-resistant materials, and there is a demand to further improve the kneading ability of the continuous kneading apparatus. Such improvement of the kneading ability is achieved, for example, by increasing the engagement between the kneading rotors. In the case of the continuous kneading apparatus of Patent Document 1, by making the distance between the axes of the pair of kneading rotors smaller than the turning outer diameter of the kneading flights, the kneading rotors can be brought into engagement with each other.

However, the increase in the degree of engagement between the kneading rotors involves a remarkable increase in the load (kneading load) applied to the kneading rotor during kneading. That is, when the kneading rotors are brought close to each other to increase the meshing, a large kneading load is applied in the direction of separating the kneading rotors from each other. This kneading load may adversely affect the kneading rotor, the bearing supporting the kneading rotor, and the like.

Therefore, in the conventional continuous kneading apparatus, the meshing between the kneading rotors can not be further increased, and it has become difficult to cope with the kneading material.

Japanese Patent Laid-Open Publication No. 2012-051363

The present invention relates to a continuous kneading apparatus provided with a pair of kneading rotors, and it is possible to provide an apparatus capable of sufficiently kneading even an egg kneading material, while suppressing the kneading load applied to the kneading rotor, .

The continuous kneading apparatus provided is a barrel having an inner cavity and a pair of kneading rotors accommodated in the barrel and rotated in an engaging manner in different directions and each kneading rotor kneads the material supplied in the barrel And the kneading flights are arranged along the axial direction of the kneading rotor. And a portion of each of the plurality of kneading flights and each of the barrels receiving the kneading flights constitutes a plurality of kneading portions arranged along the axial direction of the kneading rotor. Each of the kneading rotors is fed in the axial direction from the kneading portion on the upstream side to the kneading portion on the downstream side in accordance with the rotation of the kneading rotor so that the material is kneaded in succession in each kneading portion . In each of the kneading rotors, the kneading flight constituting the kneading portion located on the downstream side has a turning outer diameter D ₂ that is larger than the rotating outer diameter D ₁ of the kneading flight constituting the kneading portion located on the upstream side.

1 is a front view of a continuous kneading apparatus according to an embodiment of the present invention.
Fig. 2 is a graph showing changes in evaluation values by ISO for specific energies in Examples and Comparative Examples of the present invention. Fig.
3 is a diagram showing changes in gel area ratio with respect to specific energy in Examples and Comparative Examples of the present invention.
4 is a graph showing kneading loads applied to kneading rotors in Examples and Comparative Examples of the present invention.
5 is a front view of a conventional continuous kneading apparatus.

Hereinafter, the continuous kneading apparatus 1 according to the embodiment of the present invention will be described in detail with reference to the drawings.

1, the continuous kneading apparatus 1 according to the present embodiment is provided with a barrel 2 having an internal cavity and a pair of kneading rotors 3 and 3. The kneading rotor 3 3 are inserted into the barrel 2 along the axial direction thereof. The continuous kneading apparatus 1 further includes a rotation drive device (not shown) connected to the pair of kneading rotors 3 and 3 and rotating them in opposite directions. The pair of kneading rotors 3 and 3 are rotated in different directions in the barrel 2 so that shearing force is applied to the material between the pair of kneading rotors 3 and 3 and the barrel 2 And the material is kneaded.

In the following description, the left side of the sheet of Fig. 1 is referred to as the upstream side when the continuous kneading apparatus 1 is described, and the right side of the sheet is referred to as the downstream side. Further, the left-right direction of the paper surface of Fig. 2 is taken as the axial direction when describing the continuous kneading apparatus 1. Fig.

As shown in Fig. 1, the barrel 2 is formed in a long cylindrical shape along the axial direction, and its cross section in the width direction perpendicular to the axial direction is arranged in the width direction A part of the two circles is in the shape of an overlapping eyeglass (including the case where two circles overlap each other through a part of the circumference). The pair of kneading rotors 3 and 3 are inserted into the inside of the barrel 2 at positions where the axial centers of the kneading rotors 3 and 3 substantially coincide with the centers of the two circles, .

Each kneading rotor 3 is a long rod-like member extending along the horizontal direction and is supported by bearings (not shown) provided at both outer positions of both ends in the axial direction of the barrel 2, And is rotatably supported about the axis. The kneading rotors 3 and 3 are arranged such that their axial centers are parallel to each other. The pair of kneading rotors 3 and 3 are rotated in different rotational directions. That is, these kneading rotors 3, 3 are rotationally driven in different directions by the rotation drive device. More specifically, the kneading rotor 3 located on the left side in the axial direction rotates around the axis in the clockwise direction, and the kneading rotor 3 located on the right side rotates around the axis in the counterclockwise direction Direction.

The above-described continuous kneading apparatus 1 has a plurality of portions arranged along the axial direction, and six portions in the example of Fig. Specifically, these six portions are arranged in this order from the upstream side along the flow direction of the material. The first transfer portion 4, the first kneading portion 5, the throttling portion 6, the second transfer portion 7, 2 kneading section 8 and a discharging section 9. On the outer peripheral surfaces of the respective portions of the kneading rotor 3 corresponding to these portions, flights of different kinds, that is, flights having different blade shapes or wing counts, are formed. These multiple types of flights include, for example, a screw flight forming a flow for pushing and moving the material downstream in the barrel 2, and a kneading flight for applying a shearing force to the material and kneading.

Next, the first conveying unit 4, the first kneading unit 5, the throttling unit 6, the second conveying unit 7, the second kneading unit 8, and the discharging unit 9 will be described in detail do.

The first transfer part 4 is a part for feeding the material supplied in the barrel 2 from the material supply port (not shown) toward the downstream side. This material supply port is opened upward so as to communicate with the inside and outside of the barrel 2, and it is possible for the material to be supplied into the barrel 2 through the material supply port.

A screw flight 10 is formed on the outer peripheral surface of each of the kneading rotors 3 corresponding to the first transfer section 4 in a spiral shape along the axial direction of the kneading rotor 3. The screw flight 10 has such a shape as to push the material supplied from the above-described material supply port toward the downstream side along with the rotation of the kneading rotor 3 so as to move it. The screw flight 10 and the portion of the barrel 2 that accommodates the screw flight 10 constitute the first transfer portion 4. The material sent from the first transfer section 4 to the downstream side is sent to the first kneading section 5 located on the downstream side of the first transfer section 4. [

The first kneading portion 5 is a portion for applying a shearing force to the material in the barrel 2 to knead the material. A kneading flight 11 is formed on the outer circumferential surface of a portion of each kneading rotor 3 corresponding to the first kneading portion 5. This kneading flight 11 has an outer circumferential surface and the outer circumferential surface has an outer diameter that forms a narrow gap (tip clearance) between the inner circumferential surface of the barrel 2 and the outer circumferential surface of the adjacent kneading rotor 3. The material is guided to the narrow gap and is given a shearing force. That is, the portion of the kneading flight 11 and the barrel 2 that accommodates the kneading flight 11 constitutes the first kneading portion 5. The material kneaded in the first kneading section 5 is sent to the throttling section 6 located on the downstream side of the first kneading section 5.

The throttling portion 6 is located on the downstream side of the first kneading portion 5 and restricts the flow of the material between the barrel 2 and the kneading rotor 3 so that the material of the first kneading portion 5, To adjust the kneading degree of the material. Specifically, the throttling portion 6 has an opening communicating with the first kneading portion 5 and the second feeding portion 7, and the opening portion is formed by the inner diameter of the first kneading portion 5, Has an inner diameter smaller than the inner diameter of the second transfer section (7) and an inner diameter smaller than the inner diameter of the other portion. The portion of each of the kneading rotors 3 corresponding to the throttle portion 6 also has an outer diameter smaller than the outer diameter of the other portion of the kneading rotor 3. The peripheral wall of the barrel 2 corresponding to the throttle portion 6 is provided with a through hole (not shown) passing through the peripheral wall of the barrel 2 along the width direction perpendicular to the axial center of the kneading rotor 3 The plate-like gate member 13 capable of blocking the flow of the material along the axial direction is accommodated in the through hole 12 so as to be able to move in and out along the width direction perpendicular to the axial direction .

That is, in the throttle portion 6, the position of the gate member 13 in the through hole 12 is switched to the position where the gate member 13 protrudes toward the kneading rotor 3 side, The material flow rate of the material in the first kneading part 6 is reduced and the material flow rate is reduced so that the material can easily stay in the first kneading part 5 and the kneading degree of the material can be increased. Conversely, when the gate member 13 is drawn out to the outside of the through hole 12 and the position of the gate member 13 is shifted to a position away from the kneading rotor 3, The area is enlarged to increase the flow rate of the material, making it difficult for the material to stay in the first kneading portion 5, and it is possible to lower the kneading degree of the material. The material whose kneading degree has been adjusted in the shaft portion 6 in this way is sent to the second transfer portion 7 on the downstream side of the shaft portion 6.

The second transfer section 7 is a section which is kneaded in the first kneading section 5 and sends the material whose kneading degree is adjusted in the throttling section 6 toward the downstream side. The outer peripheral surface of the portion of each of the kneading rotors 3 corresponding to the second transfer portion 7 is also twisted in a spiral shape along the axial direction of the kneading rotor 3 in the same manner as the portion corresponding to the first transfer portion 4 A screw flight 14 is formed so that the screw flight 14 has a shape capable of pushing the material toward the downstream side and moving the material while the kneading rotor 3 rotates. The screw flight 14 and the portion of the barrel 2 that accommodates the screw flight 14 constitute the second transfer portion 7. The material sent from the second transfer section 7 to the downstream side is sent to the second kneading section 8 located on the downstream side of the second transfer section 7.

Like the first kneading section 5, the second kneading section 8 is a section for applying a shearing force to the material in the barrel 2 to knead the material. A kneading flight 15 capable of imparting a shearing force to the material of the barrel 2 along with the rotation of the kneading rotor 3 is formed on the outer peripheral surface of a portion of each of the kneading rotors 3 corresponding to the second kneading portion 8, Is formed. The kneading flight 15 and the portion of the barrel 2 that accommodates the screw flight 15 constitute the second kneading portion 8. [ The material kneaded in the second kneading portion 8 is sent to the discharge portion 9 located on the downstream side of the second kneading portion 8.

The discharge portion 9 is a portion for discharging the material kneaded in the first kneading portion 5 and the second kneading portion 8 out of the barrel 2. A discharge hole 16 is formed in a portion of the barrel 2 corresponding to the discharge portion 9 so as to pass through the inner wall on the lower side of the barrel 2 constituting the discharge portion 9. [ A discharge blade 17 having a shape suitable for discharging the material through the discharge hole 16 is formed in the outer circumferential surface of the portion corresponding to the discharge portion 9 of each of the kneading rotors 3, So that the material can be discharged from the barrel 2.

Fig. 5 shows a continuous kneading apparatus 101 according to a comparative example. The continuous kneading apparatus 101 also includes a barrel 102 and a pair of kneading rotors 103. The continuous kneading apparatus 101 includes a first conveying unit 104, a first kneading unit 105, The first kneading portion 106, the second feeding portion 107, the second kneading portion 108, and the discharging portion 109. However, the inner diameters of the respective portions may be the same as they are toward the downstream side in the material feeding direction, The barrel 102 is formed so that the inner diameter of the barrel 102 is reduced. Each kneading rotor 103 has a cross-sectional shape similar to that of the barrel 102, but the outer diameter of the kneading rotor 103 in the "cross section of the first kneading portion 105" Section of the kneading rotor 108 is different from each other.

Specifically, among the kneading rotor 103, a rotating outer diameter d ₁ of a portion corresponding to the first kneading portion 105, a rotating outer diameter d ₂ of a portion corresponding to the second kneading portion 108, (Outer diameter of the discharge vane) d _d of the portion corresponding to the discharge port 109, the following relationship is satisfied.

The continuous kneading apparatus 101 according to the comparative example is a non-engageable type like the conventional continuous kneading apparatus, and therefore, compared with the rotating outer diameter of the kneading rotor 103, the inter-blade distance L 'Is big. That is, in the continuous kneading apparatus 101, the following equation (2) is established in addition to the equation (1).

In recent years, however, there has been a growing demand for kneading an egg-kneading material, and in order to further improve the kneading ability, there has been developed a technique in which the distance between the pair of kneading rotors is reduced, that is, the continuous kneading apparatus is engaged . However, with the reduction of the distance between the axial centers, the kneading load applied to the kneading rotor at the time of kneading is remarkably increased, and the possibility of adversely affecting the kneading rotor and the bearing supporting the kneading rotor by such a large kneading load also increases .

Therefore, in the continuous kneading apparatus 1 shown in Fig. 1, as shown in the following formula (3), the kneading flights 15 (15) constituting the second kneading portion which is the kneading portion located at the most downstream side among the respective kneading rotors 3 ) can rotate the outer diameter D _2, it is set larger than the rotational outside diameter D ₁ of the kneaded flight (11) constituting the mixing section disposed in the first mixing-kneading section of the upstream side of the.

Concretely, since the continuous kneading apparatus 1 of the present embodiment has two kneading portions of the first kneading portion 5 and the second kneading portion 8, the " kneading portion located at the most downstream side " The second kneading portion, " the most upstream-side kneading portion " is the first kneading portion. Therefore, the continuous kneading apparatus 1 is characterized in that the outer diameter D ₂ of rotation of the kneading flights 15 constituting the second kneading portion of each of the kneading rotors 3 is smaller than the kneading flights 11 constituting the first kneading portion, Is larger than the outer diameter D ₁ of rotation of the rotor. The portion of the kneading rotor 3 corresponding to the discharge portion 9 has an outer diameter D _d (rotation outer diameter of the discharge blade) substantially equal to the outer diameter D ₂ of rotation of the second kneading portion.

In this continuous kneading apparatus 1, the rotating outer diameter D ₁ of the kneading flights 11 constituting the first kneading portion 5 of each kneading rotor 3 is set to be larger than the rotational outer diameter D ₁ of the pair of kneading rotors 3, , And the outer diameter D ₂ of rotation of the kneading flights 11 constituting the second kneading portion 8 is preferably larger than the inter-shaft distance L between the pair of kneading rotors 3, 3.

In other words, the continuous kneading apparatus 1 of the present embodiment preferably satisfies the following expression (4).

The relationship of the above-described formula (4) is such that the outer diameter D ₁ of rotation of the kneading flights 11 of each kneading rotor 3 is made to be equal to or smaller than the inter-shaft distance L so that the kneading flights 11 are not engaged with each other, The turning outer diameter D ₂ of the kneading flights 15 of the respective kneading rotors 3 is made larger than the inter-shaft distance L so that the kneading flights 15 are engaged with each other.

However, if the turning outer diameter of the kneading flight 11 or the kneading flight 15 is too small, the kneading ability is largely lowered. Conversely, if the turning outer diameter of the kneading flights 11 and the kneading flights 15 is too large, the kneading load becomes excessive. The rotation outer diameter D ₁ of the kneading flight 11 of each of the kneading rotors 3 described above and the outer diameter D ₂ of rotation and the inter-shaft distance L of the kneading flights 15 satisfy the following conditions (5) and Is satisfied.

Further, it is more preferable that the relationship between the rotation outer diameter D ₁ and the inter-axis distance L ₁ satisfies the following condition (7) in addition to the condition of the above-mentioned formula (6).

By satisfying the relationships of the above-mentioned expressions (5) and (6), preferably the expressions (5) to (7), it is possible to improve the kneading ability while suppressing the kneading load, The continuous kneading apparatus 1 can be continuously operated. That is, in the continuous kneading apparatus 1 provided with the kneading rotors 3 and 3 having the rotating outer diameters satisfying the above-mentioned equations, the continuous kneading apparatus 1 is of the non-engaging type with respect to the first kneading unit, , The kneading ability of the first and second kneading parts is improved as compared with that of the non-engaging type device, and the kneading ability of the entire continuous kneading device 1 is also high. On the other hand, since the first kneading portion which is most likely to receive the kneading load is a non-engageable type, the kneading load is not so much larger than that of a device in which both kneading portions are engaged. As a result, in the continuous kneading apparatus 1, both the effect of suppressing the kneading load applied to the kneading rotor 3 and the effect of improving the kneading ability can be achieved.

Example

Next, the operation and effect of the continuous kneading apparatus 1 according to the above embodiment will be described in more detail in comparison with the comparative example.

Also in any of Examples 1 and 2 and Comparative Examples described later, the material of the egg-kneading HDPE (high-density polyethylene resin) was kneaded at a throughput of 520 kg / h, and the specific energy applied to the material was 0.240 kWh / kg Lt; / RTI > The continuous kneading apparatuses according to Examples 1 and 2 and Comparative Example are the same as the kneading rotor 3 shown in Table 1 except that the outer diameter of the kneading rotor 3 (the outer diameter of the rotor shown in the table) and the inner diameter of the barrel 2 Quot; chamber inner diameter " shown in the table), an inter-axis distance, and a tip clearance. The rotor outer diameter D ₁₁ and the rotor outer diameter D ₂₁ shown in Table 1 correspond to the rotating outer diameter D ₁ of the kneading flights 11 constituting the first kneading portion 5 in the kneading rotor 3 described above. The rotor outer diameter D ₁₂ and the rotor outer diameter D ₂₂ shown in Table 1 correspond to the rotating outer diameter D ₂ of the kneading flights 15 constituting the second kneading portion 8 of the kneading rotor 3 described above. The rotor outer diameter D _r1 shown in Table 1 corresponds to the outer diameter d ₁ of rotation of the kneading flight 111 constituting the first kneading portion 105 of the kneading rotor 103 described above, D _r2 corresponds to the turning outer diameter d ₂ of the kneading flight 115 constituting the second kneading portion 108 of the kneading rotor 103 described above.

As shown in Table 1, in Example 1, the kneading flight 11 constituting the first kneading portion has a rotation outer diameter D ₁₁ of 93.5 mm, which is smaller than the inter-shaft distance L of 100 m. The outer diameter D ₁₂ of rotation of the kneading flight 15 constituting the second kneading portion is 120.4 mm, which is larger than the inter-shaft distance L of 100 mm and the turning outer diameter D ₁₁ of 93.5 mm. Therefore, Embodiment 1 satisfies all the relations of the above-described Equations (3) and (4).

In Example 2, the outer diameter D ₂₁ of the kneading flight 11 constituting the first kneading portion is approximately 100.9 mm, which is approximately equal to the inter-shaft distance L of 100 mm. The turning outer diameter D ₂₂ of the kneading flight 15 constituting the second kneading portion is 120.4 mm, which is larger than the outer diameter D ₂₁ and the inter-shaft distance L of 108 mm, similarly to the turning outer diameter D ₁₂ . Therefore, the second embodiment also satisfies all of the relationships of the above-described expressions (3) and (4).

On the other hand, in the comparative example, both of the first and second kneading portions are of non-engagement. Specifically, in the comparative example, the rotational outer diameter D _r1 of the kneading flight 111 constituting the first kneading portion is 93.5 mm, which is smaller than the inter-shaft distance L of 100 mm. The turning outer diameter D _r2 constituting the kneading flight 115 of the second kneading portion is 93.5 mm, which is smaller than the inter-shaft distance L of 100 mm. As a result, the comparative example does not satisfy both of the above-mentioned equations (3) and (4).

Mentioned HDPE material using the kneading rotor [3 (103)] having the rotating outer diameter as shown in Table 1 and the kneading rotor [3] (103) having the rotating outer diameter as the examples and the comparative example were kneaded and the state of gel generation in the material after kneading was measured , And the kneading rotor 3 (103) were compared. In this evaluation of the kneading performance, ISO (ISO 11420: Evaluation Method defined in 1996) and WSA (gel area ratio) for evaluating the state of gel generation in the material were used.

The ISO (ISO 11420) specifies a method for evaluating the degree of dispersion of carbon black in polyolefin pipes, joints and compounds, and is usually carried out using a polyolefin pipe containing carbon black particles, aggregate size and carbon black of less than 3% The procedure for evaluating the dispersibility in joints and compounds will be described.

Further, the WSA is an index (hereinafter, referred to as " WSA ") indicating an extent of the gel area in a predetermined observation field area (1495 mu m x 1128 mu m) based on confirmation of the gel present on the surface of the material after kneading to be. This WSA shows, for example, how much the gel portion not containing carbon exists in the case where carbon is mixed and kneaded in the material. Figs. 2 and 3 show measurement results of ISO and WSA. Fig.

Paying attention to the change of the comparative example in Fig. 2 and Fig. 3 (the example of DELTA), as the specific energy to be applied to the material increases, the evaluation value and WSA by ISO become smaller, It can be seen that the gel in the material is getting smaller. However, in the comparative example, even if kneading is performed until the specific energy is reduced to about 0.240 kWh / kg, the evaluation value and the WSA by ISO are reduced only to a certain extent, and the degree of decrease is obvious compared with Example 1 or Example 2 low.

In addition, paying attention to the change in Example 1 (the legend of?) Or Example 2 (the legend of?), Regardless of the change of the specific energy applied to the material, the evaluation value by ISO and the WSA remain small . This indicates that the apparatuses according to Examples 1 and 2 can perform kneading from the start of kneading to the point where a large kneading ability is exerted and the gel almost disappears. Therefore, as in the case of the first embodiment or the second embodiment, it is judged that an excellent effect that the kneading ability can be greatly improved can be exerted when the relations of the above-mentioned equations (3) and (4) are all satisfied.

On the other hand, FIG. 4 shows the results of measurement of the kneading load applied to the kneading rotor 3 in the examples and the comparative examples under various operating conditions. The results of the comparative example shown in Fig. 4 show the kneading load applied to the kneading rotor 103 of the comparative example in the non-engaged state. The kneading load applied to the kneading rotor 103 is 700 kgf to 1700 kgf and is lower than the design upper limit of 3000 kgf of the load bearing applied to the kneading rotor 103.

In the engaged state in which the kneading rotors 3 are in close proximity until the rotation outer diameter D ₁ or the rotation outer diameter D ₂ exceeds the inter-shaft distance L, the value of the kneading load rises to about two to three times, Which is higher than the design upper limit of 3000 kgf, and the possibility of breakage of the kneading rotor 3 or damage to the bearing supporting the kneading rotor 3 can not be ignored.

With respect to such a comparative example, in the first and second embodiments which satisfy the above-described expressions (3) and (4), even though the kneading rotors 3 are in engagement with each other, The kneading load is in the range of 1300 kgf to 2500 kgf and does not exceed the design upper limit of 3000 kgf. From this, it can be seen that, in the case where all of the relationships of the above-described expressions (3) and (4) are satisfied as in the case of the first or second embodiment, it is possible to improve the kneading ability, Able to know.

As described above, with respect to each kneading rotor 3 in the continuous kneading apparatus 1, the rotating outer diameter D ₂ of the kneading flight 15 constituting the kneading portion located on the downstream side is the same as the rotating outer diameter D ₂ of the kneading portion constituting the kneading portion on the upstream side By making the rotation outer diameter D ₁ of the kneading flight 11 larger than the rotation outer diameter D ₁ of the kneading flight 11, the kneading load applied to the kneading rotor 3 can be suppressed and the kneading rotors 3 can be meshed with each other, .

It is also to be understood that the embodiments disclosed herein are by way of illustration and not of limitation in all respects. Particularly, in the presently disclosed embodiment, matters that are not explicitly disclosed, for example, operating conditions, operating conditions, various parameters, dimensions, weight, volume, But a value that can be readily assumed by a person of ordinary skill in the art is adopted.

For example, in the above-described embodiment, among the plurality of kneading portions arranged along the axial direction, the rotational outer diameter D ₁ of the kneading flight forming the most upstream kneading portion and the kneading portion constituting the kneading portion located at the most downstream side The continuous outer diameter D ₂ of the flight satisfies the following equations (3) to (7). However, in the continuous kneading apparatus of the present invention, the kneading flight constituting the most upstream kneading section and the kneading flight constituting the most downstream side kneading section The above equations (3) to (7) are not limited. That is, even if the kneading portions other than the most upstream side or the downstream side are relatively close to each other, the relationship between the rotational outer diameters of the kneading flights constituting the kneading portions located on the upstream side and the downstream side, Can be considered to be included in the continuous kneading apparatus of the present invention.

As described above, in the continuous kneading apparatus equipped with a pair of kneading rotors, it is possible to increase the engagement between the kneading rotors while suppressing the kneading load applied to the kneading rotor, and a device capable of sufficiently kneading / RTI > The continuous kneading apparatus includes a barrel having an inner cavity and a pair of kneading rotors accommodated in the barrel and rotated in a state of being engaged with each other in different directions and each kneading rotor kneads the material supplied in the barrel And the kneading flights are arranged along the axial direction of the kneading rotor. And a portion of each of the plurality of kneading flights and each of the barrels receiving the kneading flights constitutes a plurality of kneading portions arranged along the axial direction of the kneading rotor. Each of the kneading rotors is fed in the axial direction from the kneading portion on the upstream side to the kneading portion on the downstream side in accordance with the rotation of the kneading rotor so that the material is kneaded in succession in each kneading portion . In each of the kneading rotors, the kneading flight constituting the kneading portion located on the downstream side has a turning outer diameter D ₂ that is larger than the rotating outer diameter D ₁ of the kneading flight constituting the kneading portion located on the upstream side.

In this continuous kneading apparatus, by reducing the outer diameter D ₁ of rotation of the kneading flight constituting the kneading portion located on the upstream side of each of the kneading rotors, the kneading portion located on the downstream side is constituted By increasing the turning outer diameter D ₂ of the kneading flight and increasing the engagement of the kneading portions on the downstream side, it is possible to sufficiently knead the kneading material.

Preferably, the plurality of kneading portions include a first kneading portion and a second kneading portion arranged at a distance in the axial direction of the kneading rotor, wherein the pair of kneading rotors are arranged such that their axial centers are parallel to each other Wherein the kneading flights constituting the first kneading portion of the kneading flights of the respective kneading rotors have a rotating outer diameter D ₁ smaller than the inter-shaft distance L between the pair of kneading rotors, 2 kneading portion has a turning outer diameter D ₂ that is larger than the inter-shaft distance L between the pair of kneading rotors. As described above, the first kneading portion having the turning outer diameter D ₁ smaller than the inter-shaft distance L contributes to the suppression of the kneading load by being spaced apart from each other, while the second kneading portion having the turning outer diameter D ₂ larger than the inter- By engaging with each other, it contributes to improvement of the kneading ability.

More specifically, among the plurality of kneading portions, the first kneading portion including the kneading flight having the rotating outer diameter D ₁ is disposed on the most upstream side, and the kneading flight having the rotating outer diameter D ₂ , 2 kneading portion is disposed at the most downstream side.

Claims (3)

A continuous kneading apparatus comprising:
A barrel having an inner cavity,
Wherein the kneading rotor is a pair of kneading rotors housed in the barrel and rotating in a state of being engaged with each other in different directions, each of the kneading rotors having a plurality of kneading flights for kneading the material supplied in the barrel, And arranged along the axial direction of the rotor,
Wherein a portion of each of the plurality of kneading flights and each of the barrels accommodating the kneading flights constitutes a plurality of kneading portions arranged along the axial direction of the kneading rotor and each of the kneading rotors is associated with rotation of the kneading rotor The material fed into the barrel is fed in the axial direction from the kneading portion on the upstream side to the kneading portion on the downstream side so that the material is kneaded successively in each kneading portion,
Wherein the kneading flights constituting the kneading portion located on the downstream side of each of the kneading rotors have a turning outer diameter D ₂ which is larger than the outer diameter D ₁ of rotation of the kneading flight constituting the kneading portion located on the upstream side. The method according to claim 1,
Wherein the plurality of kneading portions include a first kneading portion and a second kneading portion arranged at a distance in the axial direction of the kneading rotor,
Wherein the pair of kneading rotors are arranged such that their axial centers are parallel to each other,
The kneading flight constituting the first kneading portion of the kneading flights of each of the kneading rotors has a turning outer diameter D ₁ smaller than the inter-shaft distance L between the pair of kneading rotors,
Wherein the kneading flights constituting the second kneading portion among the kneading flights of the respective kneading rotors have a turning outer diameter D ₂ larger than the inter-shaft distance L between the pair of kneading rotors. 3. The method of claim 2,
Wherein the first kneading portion including the kneading flight having the turning radius D ₁ among the plurality of kneading portions is disposed on the most upstream side and the second kneading portion including the kneading flight having the turning radius D ₂ is disposed on the most downstream side In the continuous kneading apparatus.

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